TY - JOUR
T1 - Probing jet base emission of M87* with the 2021 Event Horizon Telescope observations
AU - The Event Horizon Telescope Collaboration
AU - Saurabh,
AU - Müller, Hendrik
AU - Von Fellenberg, Sebastiano D.
AU - Tiede, Paul
AU - Janssen, Michael
AU - Blackburn, Lindy
AU - Broderick, Avery E.
AU - Chavez, Erandi
AU - Georgiev, Boris
AU - Krichbaum, Thomas P.
AU - Moriyama, Kotaro
AU - Nair, Dhanya G.
AU - Natarajan, Iniyan
AU - Park, Jongho
AU - West, Andrew Thomas
AU - Wielgus, Maciek
AU - Akiyama, Kazunori
AU - Albentosa-Ruíz, Ezequiel
AU - Alberdi, Antxon
AU - Alef, Walter
AU - Algaba, Juan Carlos
AU - Anantua, Richard
AU - Asada, Keiichi
AU - Azulay, Rebecca
AU - Bach, Uwe
AU - Baczko, Anne Kathrin
AU - Ball, David
AU - Baloković, Mislav
AU - Bandyopadhyay, Bidisha
AU - Barrett, John
AU - Bauböck, Michi
AU - Benson, Bradford A.
AU - Bintley, Dan
AU - Blundell, Raymond
AU - Bouman, Katherine L.
AU - Bower, Geoffrey C.
AU - Bremer, Michael
AU - Brissenden, Roger
AU - Britzen, Silke
AU - Broguiere, Dominique
AU - Bronzwaer, Thomas
AU - Bustamante, Sandra
AU - Carlos, Douglas F.
AU - Carlstrom, John E.
AU - Chael, Andrew
AU - Chan, Chi Kwan
AU - Chang, Dominic O.
AU - Chatterjee, Koushik
AU - Chatterjee, Shami
AU - Pu, Hung Yi
N1 - Publisher Copyright:
© The Authors 2026.
PY - 2026/2/1
Y1 - 2026/2/1
N2 - We investigate the presence and spatial characteristics of the jet base emission in M87* at 230 GHz, enabled by the significantly enhanced (u,v) coverage in the 2021 Event Horizon Telescope (EHT) observations. The integration of the 12-m Kitt Peak Telescope (USA) and NOEMA (France) stations into the array introduces two critical intermediate-length baselines to SMT (USA) and IRAM 30-m (Spain), providing sensitivity to emission structures at spatial scales of ~250 μas and ~2500 μas (~0.02 pc and ~0.02 pc). Without these new baselines, previous EHT observations of the source in 2017 and 2018 lacked the capability to constrain emission on large scales, where a "missing flux"of order ~1 Jy is expected to reside. To probe these scales, we analyzed closure phases-robust against station-based gain calibration errors-and model the jet base emission using a simple Gaussian component offset from the compact ring emission at spatial separations > 100 μas. Our analysis revealed a Gaussian feature centered at (ΔRA ~ 320 μas, ΔDec. ~ 60 μ as), projected separation of ~5500 AU, with an estimated flux density of only ~60 mJy, implying that most of the missing flux identified in previous EHT studies had to originate from different, larger scales. Brighter emission at the relevant spatial scales is firmly ruled out, and the data do not favor more complex models. This component aligns with the inferred position of the large-scale jet and is therefore physically consistent with the emission of the jet base. While our findings point to detectable jet base emission at 230 GHz, the limited coverage provided by only two intermediate baselines limits our ability to robustly reconstruct its morphology. Consequently, we treated the recovered Gaussian as an upper limit on the jet base flux density. Future EHT observations with expanded intermediate baseline coverage will be essential to constrain the structure and nature of this component with higher precision.
AB - We investigate the presence and spatial characteristics of the jet base emission in M87* at 230 GHz, enabled by the significantly enhanced (u,v) coverage in the 2021 Event Horizon Telescope (EHT) observations. The integration of the 12-m Kitt Peak Telescope (USA) and NOEMA (France) stations into the array introduces two critical intermediate-length baselines to SMT (USA) and IRAM 30-m (Spain), providing sensitivity to emission structures at spatial scales of ~250 μas and ~2500 μas (~0.02 pc and ~0.02 pc). Without these new baselines, previous EHT observations of the source in 2017 and 2018 lacked the capability to constrain emission on large scales, where a "missing flux"of order ~1 Jy is expected to reside. To probe these scales, we analyzed closure phases-robust against station-based gain calibration errors-and model the jet base emission using a simple Gaussian component offset from the compact ring emission at spatial separations > 100 μas. Our analysis revealed a Gaussian feature centered at (ΔRA ~ 320 μas, ΔDec. ~ 60 μ as), projected separation of ~5500 AU, with an estimated flux density of only ~60 mJy, implying that most of the missing flux identified in previous EHT studies had to originate from different, larger scales. Brighter emission at the relevant spatial scales is firmly ruled out, and the data do not favor more complex models. This component aligns with the inferred position of the large-scale jet and is therefore physically consistent with the emission of the jet base. While our findings point to detectable jet base emission at 230 GHz, the limited coverage provided by only two intermediate baselines limits our ability to robustly reconstruct its morphology. Consequently, we treated the recovered Gaussian as an upper limit on the jet base flux density. Future EHT observations with expanded intermediate baseline coverage will be essential to constrain the structure and nature of this component with higher precision.
KW - Accretion, accretion disks
KW - Black hole physics
KW - Galaxies: individual: M 87
KW - Galaxies: jets
KW - Gravitation
KW - Relativistic processes
UR - https://www.scopus.com/pages/publications/105029076022
UR - https://www.scopus.com/pages/publications/105029076022#tab=citedBy
U2 - 10.1051/0004-6361/202557022
DO - 10.1051/0004-6361/202557022
M3 - Article
AN - SCOPUS:105029076022
SN - 0004-6361
VL - 706
JO - Astronomy and Astrophysics
JF - Astronomy and Astrophysics
M1 - A27
ER -